Rotary steam engine



R. Lf BAILEY ROTARY `STEAM ENGINE Aug. 23, 1938.

Filed Sept. 3, 1935 3 Sheets-Sheet 1 JNVENTOR. ROBERT L. BAlLEY wf ATTOR EY N di Agg. 23, 1938. R. 1 BAILEY '2,127,963

' ROTARY* STEAM ENGINE Filed Sept. 3, 1955 5 Sheets-Sheet 2 Flc; 3

D* Q LL INVENTOR.. U 4 ROBERT L. BAILEY BY Aug.V 23, 1938. R, BlLEY 2,127,968

' v ROTARY STEAM ENGINE Figed Sept. 3, 1935 3 Sheets-Sheet 3 INVENTOR. ROBERT I .BAlLl-:v

@ .I ATTO EY Patented Aug. 23, 193s 2,127,968L

UNITED STATES PATENT OFFICE ROTARY STEAM ENGINE Robert L. Bailey, Glendale, Calif.

Application SeptemberV 3, 1935, Serial No. 38,895

7 Claims. (C1. 121-57) This invention relates to engines propelled by are parallel to and equidistant with the plane steam or other gaseous fluids and in particular, surfaces provided on the outside ring. A pluthe invention relates to steam engines of the rality of equally spacedv pins are mounted berotary type. tween the cover plates on a circle concentric Bi It is an object of my invention to provide a with the center of the cover plates. An internal rotary steam engine which shall be as nearly as rotor provided with bearings for the'eccentric of possible perfectly balanced, capable of being opthe aforementioned eccentric shaft is mounted on erated at a very high speed and free from excesthe eccentric and within the external rotor. The sive friction. internal rotor is thus mounted in an eccentric 10 A further object of my invention resides in the position With respect to the external rotor. The 10? provision of a rotary steam engine which is capainternal rotor is pro-vided With a plurality of ble of operating eiilciently with a minimum equally spaced recesses on a circle concentric amount of vibration and noise. with the center bore of the internal rotor'. The

A further object of my invention resides in a circumferences of the recesses are adapted to endevice which is small in comparison with the gage with the circumferences of the pins so that 15? work. it can perform, Which is light in weight and when the external rotor is rotated, the internal which Amay be produced at a very low cost. rotor is compelled to rotate synchronously there- Briefly stated, the rotary engine forming the with .and in the same direction. The internal subject of my invention comprises. an external rotor is also provided with a plurality of equally rotor and an internalv rotor suitably mounted spaced and radially disposed slots to receive 20 Within the external rotor,. on an axis which is vanes, the outer ends of which are adapted to non-concentric with the axis of the external engage with the plane surfaces of the outer ring, rotor. The internal rotor is operatively conwhile the inner ends are adapted to engage the nected to the external rotor. so as to revolve synprojecting rings. The plane surfaces are for the chronously therewith and in the same directionpurpose of allowing the vanes to slide back and 25 A plurality of vanes are movably mounted. in one forth as the rotors are rotated. The vanes divide of the rotors and are movably engaged with the the space between the two rotors into a plurality other rotor so as todivide the space between. the of non-communicating chambers. 'I'he number two rotors into a plurality ofr non-communicating of such chambers will be determined by the numchambers. A plurality of ports are also provided ber of vanes. Located along the side of each slot 30 in the internal rotor which communicate with and on the center of the internal rotor, a port is the spaces or chambers divided by the vanes. An provided which extends from the periphery of intake line is provided for the introduction of the internal rotor to the centralbore of the insteam or other gaseousuid and an exhaust line ternal rotor. The ports thus communicate With is provided for the exhausting of the used fluid. the chambers at one extremity and with the ec- 35 Valved means arel provided for controlling the incentric at the other extremity. These ports serve troduction` of the steam. or other gaseous fluid .as both intake and exhaust ports depending upon into` the chambers. the position of the internal rotor with respect to Stated more specifically, the rotary engine the eccentric and the slide valve unit to be de- 4l) forming the subject of my invention may be described. About the eccentric portion of the ec- 40 scribed as comprising an outside ring substancentric shaft and adapted to slide thereon, avalve tially in the shape of a hollowv cylinderwith a unit is provided for the purpose of controlling the pair of cover plates mounted on each side of the passage of steam or other gaseous fluid into the outside ring, said outside ring and cover plates ports. The slide valve unit is provided with a i5 comprising an external rotor. The'inner circumplurality of ports which are adapted to control 45 ference of the outside ring is provided with a the direction of rotation of the rotors. Complurality of equally spaced plane surfaces or flats; municating with the ports in the slide valve unit, The central portion of each cover* platev is reintake and exhaust passageways are provided in cessed to receive a bearing for the non-eccentric the eccentric shaft which communicate with inshaft about which the external rotor may be retake and exhaust'lines for the purpose of .admit- 50 volved. On the interior `surfaces of each cover ting steam or other gaseous fluid into the non- Dlate, a projecting fing iS DIOVdSd Which is pO- communicating chambers and exhausting steam sitioned in a circle which; is concentric with the therefrom, respectively. A particular feature of recesses in the cover plates. Plane surfaces or the'invention resides in the provision of a rotary flats are provided on each projecting ring which sleeve valve in the intake passageway for admit- 55 ting the steam or other gaseous fluid into a chamber which is in a partially enlarged position; this is for the purpose of starting the rotation of the rotors. The rotary sleeve valve is adapted to be turned to such a position that the port therein may be made to register with either of two intake passageways provided in the eccentric shaft which communicate with the main intake passageway and with corresponding registering ports in the slide valve unit so that the steam may be introduced into the chambers in the starting positions. The rotary sleeve valve may also be turned to register with another intake passageway and corresponding registering ports in the slide valve unit so that the steam may be introduced into the chambers in the desired running position.

Other objects, features and advantages of my invention will become apparent to those skilled in the art from the following description of my invention taken from the drawings which is not to be considered as limiting my invention.

Fig. l is a cross-sectional elevation of the device taken along line I I of Fig. 2 parts being shown broken away.

Fig. 2 is a section of the device taken along line 2 2 of Fig. 1.

Fig. 3 is a section similar to Fig. 2 but on a smaller scale of the device with parts broken away so as to show details of the device.

Fig. 4 is a sectional elevation taken along line `3 3 of Fig, 5 illustrating the slide valve unit and parts connecting therewith to operate the same.

Fig. 5 is an elevation of the slide valve unit and connecting parts parts being shown in section and parts being shown broken away.

Fig. 6 is a section illustrating the position of the slide valve unit and rotary sleeve valve in starting position for counterclockwise rotation of the device.

Fig. 7 is a cross-section taken along line 5 5 of Fig. 8 and illustrates the position of the slide valve unit and rotary sleeve valve in running position for counterclockwise rotation of the device.

Fig. 8 is a cross-section taken along line 4 4 .0f Fig. 7.

v ing position for clockwise rotation of the device.

Fig. 10 is a cross-section taken along line 'I 'I of Fig. l1 and illustrates the position of the slide valve unit and rotary sleeve valve in running postion for clockwise rotation of the device.

Fig. 11 is a cross-section taken along line 6 6 of Fig. 10.

Fig. 12 is a cross-section taken along line 9 9 of Fig. 13 and illustrates the position of the slide valve unit in neutral position.

Fig. 13 is a cross-section taken along line 8 8 of Fig. 12.

Referring more particularly to the drawings wherein like reference numerals refer to corresponding parts throughout the several views, I denotes an outside ring which is substantially in the shape of a hollow cylinderand is fastened to circular left and right cover plates 2 and 3, respectively, by means of a plurality of bolts 4. The outside ring I and the cover plates 2 and 3 form an assembly which shall be referred to hereinafter as the external rotor.

At the center of the left cover plate 2, a recess is provided to receive a bearing 5 for left portion 6 of the eccentric shaft 1. A hub 8 is also provided to which is fastened stub shaft 9 by bolts il). The stub shaft may be connected to a pulley or gear which may in turn be connected to the device to which it is desired to transmit the power. The right cover plate is substantially similar in construction as the left cover plate with the exception that a larger bearing II is provided for right portion I2' of eccentric shaft 1, which is of greater diameter than shaft 5. The remaining portion of the shaft I2 extends through the cover plate and is supported by a suitable bearing I4 which is suitably mounted on frame I5. Thus, the external rotor is so provided as to revolve about fixed axis I6 on bearings 5 and II. It will be observed that during rotation of the external rotor and the internal rotor to be described, the eccentric shaft remains stationary while the rotors revolve about the shaft. If desired, the portion of the eccentric shaft passing through the bearing I4 may be provided with a keyway and key or a set screw to prevent the shaft from revolving when the rotors are rotated.

An internal rotor I'l provided with bearings I'la.

is mounted in the interior of the external rotor so as to revolve about fixed axis i8 on eccentric I9 of the eccentric shaft 'i'. Shafts '5, E2 and I9 form the eccentric shaft l. Shafts E and I2 have a common fixed axis II, while the fixed axis I8 is eccentrically positioned with reference to the axis I6 of the external rotor. By the arrangement shown in the drawings, the internal rotor revolves inside of the external rotor but nearer to one side than to the other due to the eccentric positioning of eccentric I9 with respect to shafts 6 and I2. Preferably, the internal rotor is so positioned eccentrically in the external rotor that one end substantially contacts the inner surface of the external rotor to provide an oil seal. This will cause substantially all of the used steam or other gas to be forced out of the chamber after its propelling force has been spent.

The internal and external rotors revolve synchronously. This effect may be produced in various ways without departing from the spirit of my invention. In the method illustrated in the drawings, a plurality of equally spaced circular recesses 20 are provided in the internal rotor about a circle concentric with the axis I8 and an equal number of pins ZI extending through the recesses are mounted between the left and right cover plates about a circle concentric with axis I5. The right end 22 of the pins is threaded in the right cover plate 3, while the left end which is similarly threaded is fixed to the left cover plate by means of a screw 23. 'Ihe pins are provided in such position as to engage the internal circumferences of the recesses 2?. Thus, by this means, when the external rotor is revolved on shafts 5 and I2 or in other words, about fixed axis I5, by the steam introduced into the chambers, the internal rotor II is also compelled to revolve in the same direction due to engagement with pins 2I. However, the rotor I'I revolves freely about eccentric I9 or in other words about its own fixed axis i8. The recesses 20 may be of any diameter but in order to obtain the synchronized rotation of the internal and external rotors, the radius of the recesses 2l! is made equal to the sum of the distances between axes I6 and I8 of the two rotors and the radius of the pins 2 I.

A plurality of equally spaced and radially disposed slots 24 are provided in the internal rotor to receive vanes 25 which are substantially rectangular in shape and of a thickness substantially equal to the width of the slots. This is for the purpose of dividing the space between the two rotors into as many non-communicating chambers as. there are vanes as will be more fully explained hereinafter.

Projecting. rings 2li` are provided on' the inner surfaces of both coverplates and are formed around the center thereof. These rings are providedwith as many plane'surfaces or flats 21 as there are numbers of vanes. Theedges of the plane lsurfaces ofthe projectingv ring on one cover plate are.l parallelv to those. on4 the other cover plate. Correlated plane surfaces 23 are formed on the inner surfaces of the. outside ring I.V The vanes are. positioned in the. slots 24 and are provided at their inner endsr with slots so'. asiV to engage the projecting rings 2B. The outer'fends of the vanes are adapted to slide along the plane surfacesf28" of the'outside ring I. Thus, withA the-vanes positioned as described, when the external rotor is revolved, which also causes the internal rotor to.` revolve in the same direction,

. the inner end of vanes. 25 slides along plane surfaces 2'1 of the projecting rings and plane surfaces 28 of/ the external rotor, while the upper and. lower sides of the vanes slide along the outer portions of the inside surfaces of the. cover plates. The vanes also slide backward and forward in the slots as will be more fully. described'- While preferably I provide two projecting rings in the device, it is to be understood that I m-ay dispense with 'one of said projecting rings and thus provide only one with the desired number of plane surfaces for carrying the. vanes. This will be vunderstood by those skilled in the art.

To one side of each` slot 24, ports 30 are drilled substantially radially throughv the center of the internal rotor which extend into the central bore of the internal rotor. These ports function as both intake andA exhaust ports for the steam or other-gaseous fluid employed as theA operating force-for the.` rotation of the rotors as will be described hereinafter more fully. Thus, the ports communicate at their outer ends with the space between the internal and vexternal rotors. The eccentricI I9 of the eccentric shaft 1 is provided with a vertical passageway 3l which communic-ates with a longitudinally disposed passageway 32 drilled through the center of the eccentric shaft which, in turn, is connectedy with an inlet pipe 33; The eccentric I9 is also provided with passageways 34` and. 35 which also communicate with. the longitudinally disposed passageway 32. A sleeve 36 extends throughout thez entire length of passageway 32.` The sleeve is provided with a port 31' and is adapted to be rotated in the passageway by' lever 38 so that the port 31 may be made toregister with either one of the passageways 3|., 34 or 35. Thus, sleeve 36 operates as a rotary valve- Adjacent and parallel to passageway 32, a similarl passageway 39 is provided. which connects with an exhaust pipe 4U. Passageway 39 and exhaust pipe 40 serve to exhaust the used steam or other gas from the chambers.

In the inner bore of the internal rotor I1 and positioned. about eccentric I 9 and adapted to slide thereon, aslide valve unit 4I 'is provided which is made up of an inner sleeve 42 and an outer sleeve 43. The sleeve 42 ts very closely in the outer sleeve 43 so as to prevent it from sliding or otherwise moving in the sleeve 43. If desired, the two sleeves m-ay be madey integrally. Sleeve 42 is provided with ports 44 and 45 which are in line, respectively, Withports 46 and 41 of the outer sleeve. Ports 44v and 46 and ports 45 and 41: serve to admit the steam into the chambers for the purpose of starting the rotation of the rotors. Ports 481 and 49: are provided in the sleeves which: areadapted to communicate with passageway 3I for the purpose of operating the device in= running. position as Will" be described hereinafter more fully. The inner sleeve 42 is also provided with. exhaustlportsy 50' and 5I which communicate with portsA 52 and 53, respectively, of the outer sleeve. Ports 52 and 53 are larger than ports-..50 and 5Irespectively. AThis is for the purpose. of exhausting steamy from 'a plurality ofy chambers simultaneously and thus providing a morey complete exhausting ofthe used steam from the chambers.

' The' slide valve unit 4lV iscaused to slide on eccentric ISA by means of rods 54which extend through longitudinal passagewaysA provided in the shaft 1. and are connected to a lever arrangement 55'.. The rods 54 are provided with lugs 56 which carry the sleeves 42 and 43. Thus, when the lever 55Pispulled outwardly as shown in Fig. 1, the steam: to `rotate the rotors is admitted through port 48 and passageway 3| into the chamber via ports 30 in the internal rotor. This will. cause the rotors to` rotate in a counterclockwise direction. In this position, the steam is exhaust'ed through ports 5I! and 5.2.v When the lever 55 isv pushed towards the device, the slide valvey unit. is caused to slide along the eccentric |13 and: when port 49 registers with passageway 3If, thel steam'will be admitted through this port into the chambers via portsx30 and the rotors will be rotated in' a4 clockwise direction. In this position,A the steam is exhausted through ports 5I and 53..

WhileI have described the' essential features of, theV device forming the subject matter of my invention, there will be apparent to those skilled in the art, many improvements which will result in a, smooth and eflicient operation of the device.. While I have not shown means for lubricating the device, provision may be made for lubricating the various working parts such as the bearings, vanes and pins. Provision may also bemade to prevent leakage of the steam or other motivating gas employed. For example, sealing lrings may be providedbetween the surface of. the. eccentric: and the inner sleeve 42 by providing grooves. in the inner surface of.` the inner sleeve tov receive-the rings. I have shown means to prevent leakage of the steam from the right cover plate 3. This consists in'a packing ring 51 which is fastened to the end of the coverv plate by meansfof screws 58'. The space 59 between the cover plate and the packing ring may be lled with. any desired packing material;

vWhile I have shown the space between the internalA and vexternal rotors as being divided into six chambers, it is obvious that thisspace may be' divided into a greater or lesser number by providing the necessary number of vanes, etc. I have describeda device with six chambers but there is no reason why the device cannot be made to` operate satisfactorily with a different number of chambers'.

f IForconvenience in describing the operation of the device, Ihave indicated the various chambers shown in Fig. 2 as A, B, C, D, E, and F, the vanes as A', B', C', D', E' and F', and the ports in the internal rotor as A", B", C, D", E and F. Referring more particularly to Fig. l2 of the drawings, `the chamber A is in a position where the steam has beenI admitted into the chamber and the chamber has rotated only a few'degrees, the steam having been introduced into the chamber via line 33, passageways 32 and 3| and port A. The expansion of the steam in the chamber causes the rotors to rotate in the counterclockwise direction indicated by the arrow. The expansion of steam in the chamber continues until the expansive force is dissipated by the gradual increase in the volume of the chamber, after which the port A is opened to the exhaust ports 50 and 52 as shown by port C. The chamber is then ready to start the exhaust cycle. The exhausting continues until the chamber reaches the position as shown by port F after which it is sealed off from the exhaust passageway and the chamber is then ready to take another charge of. steam. During the rotation of the rotors, the chambers each assume the various positions A, B, C, D, E and F. Each of said positions represents 60 of rotation, this gure being arrived at by dividing the number of chambers into 360. Thus, at position C, the chamber is starting to exhaust. At the 180 point, it is still in communication with the exhaust port and continues to do so until approximately at position F. Thus, as shown in Fig. 2, chambers C, D and E are exhausting steam from the chambers while chamber F has just about completed the exhausting cycle. The exhausting of steam from the chambers D and E is aided by the narrowingof the chambers in volume due to the eccentric positioning of the rotors. Chamber C is also shown as commencing the exhausting cycle. However, this occurs prior to its reaching its maximum volume. It is desirable to start the exhaust cycle from the chamber prior to its reaching its maximum volume in order to prevent any back pressure in the chambers and thus retarding the rotation of. the rotors. When the port 30 of any chamber registers with ports 3| and 48, the latter two ports being continuously in registering position when the device is in running position, the chamber is ready to receive a fresh charge of steam and thus start a new cycle. The introduction of the steam into the chambers is preferably ahead of top dead center and continues beyond the top dead center. The interval of steam introduction into the chambers is very short. For example, I may start the introduction of the steam about 20 before the chamber reaches top dead center and continue the introduction approximately 20 past top dead center. The expansion of the steam then continues for approximately after the intake port closes.

As indicated above, the rotation of the rotors causes the vanes to slide along the plane surfaces 2l and 28 and in the slots 24. As the rotors are revolved, the vanes 25 are at all times substantially radial to the inner rotor. The vanes are furthest in the slots when the chambers are substantially at top dead center, that is, at the 0 position. At this position, the vanes are also centrally disposed in the plane surfaces. The uppermost vane in Fig. 2 is shown at substantially top dead center. As the rotors revolve in the direction indicated by the arrow from the aforesaid position, the vanes slide in a clockwise direction towards one end of the plane surfaces. Due to the eccentricity of the internal rotor with respect to the external rotor, the vane will have risen in the slot with reference to the external rotor thus enlarging the volume of, space A. When the device has rotated 90 from the start, the vane will have traveled to the furthermost clockwise position. Continued rotation of the rotors causes the vane to slide along the plane surfaces in a counterclockwise direction or in the same direction as that of the rotors. When is reached, the position of the vane in the plane surfaces is precisely the same as it was at the 0 position. At this point, the vane will have risen to its outermost position in the slot. As the revolution continues, when 270 is reached, the vane has traveled along its plane surfaces to the farthest point in the opposite direction and is ready to return. Further rotation causes the vane to travel in a clockwise direction to the center of the plane surfaces when the rotors have been revolved 360.

In Fig. 2 of the drawings, I have indicated by arrows on the vanes the direction of travel of the vanes at their various positions. Thus, vanes A and B are shown as moving in a clockwise direction and will continue to do so until the 90 point is reached, after which its direction is reversed as shown by vanes C', D and E. At 180 the vane will have been centrally located in the plane surface 28 as shown by vane D. At 270 the vane will have moved to the extreme opposite position after which further rotation resumes the clockwise direction of travel of the vane until the revolution has been completed. Vane F' indicates the direction of. travel after the vane has passed the 270 point. Fig. 3 also shows the direction that the vanes slide in their respective plane lsurfaces as the rotors are revolved.

It does not seem necessary to describe the action of the recesses 20 and pins 2| at any considerable length. It is evident that as the rotors revolve, the eect of the distance between the radii of the two rotors is continually keeping the pins 2| pressed against the internal surfaces of the recesses 20 as shown in the drawings. The rotors will, therefore, be held continually in the same relation to each other while each chamber will move about the axis ofthe external rotor.

Sliding of the valve umt 4| on the eccentric by means of lever 55 and rods 54 to a position so that the port 3| is centrally located or is between ports 48 and 49, the steam will be shut off, thus preventing rotation ofthe rotors. The valve unit will then be in a neutral position as shown in Figs. 12 and 13. If it is desired to cause the rotors to rotate in a, counterclockwise direction, valve unit 4| is moved to its extreme right hand position by means of lever 55 so that port 4B registers with port 3| as shown in Fig. 8. Lever 38 is then revolved in a counterclockwise direction which causes the sleeve 36 to revolve until port 31 in the sleeve registers with passageway 34 as shown in Fig. 6. Steam will then be introduced into the chamberhaving its port 30 registering with port 46. The purpose of starting the rotation of the rotors in this position is to facilitate starting. By introducing steam into a chamber which is in a partially enlarged position, a greater impulse will be given to the rotors. If the steam is introduced into a chamber which is in substantially a position having its smallest volume, such as at top dead center, the steam may not give the rotors the starting impulse.

Once the device has been started, lever 38 is moved to a vertical position or to a position where port 31 in the sleeve 36 registers with port 3| as shown in Fig. 7. This will seal off passageway 34. The steam will then be introduced into the chambers via ports 30 when the chambers almost reach the 0 position. This will constitute the running position of the valve unit and the sleeve valve for counterclockwise rotation. 'I'he reason for providing port 46 larger than port 48 is to give the device a larger amount of steam so as .to provide the necessary starting torque. Once rthe device is under rotation, the amount'of. steam .necessary to keep it running need not be as great. Hence, port 48 is reduced in size.

If `it is desired to revolve the device in a clockwise direction from the neutral position, the valve unit 4I is moved to the extreme left hand position by meansof lever 55 and its associated rods 54 so as to register port 49 with port 3| as shownin Fig. 11. Lever 38 is then revolved in a clockwise direction until the port 31 in the sleeve registers with the passageway 35 as shown in Fig. 9. This will admit steam into the chamber having its port.30 registering with port 41 and vthus give the device :its starting impulse. Once the -device is started, the lever 38 is returned to a vertical positionso asto register port 3T in the sleeve with passageway 3| and port 49 as shown in Fig. 10. This constitutes the clockwise running position of thedevice.

`.In actual operation, the speed of rotation of the rotors is controlled by the amount of steam introduced into thechambers. The amount of steam thus introduced may be controlledby a valve (not shown.) on 1ine33 which is connected to a source of steam.

It is to be understood that the above description is vmerely illustrative of a preferred embodiment of my invention of which many variations thereof may be made within the scope of the following claims by those skilled in the art without departing from the spirit thereof.

Having now described my invention, what I claim as new and. desire to secure by Letters Patent is:

l. In a gaseous fluid engine, an external rotor provided with a plurality of plane surfaces and mounted on a shaft, projecting rings in said extern'al rotorprovided with plane surfaces parallel to said rst mentioned plane surfaces, an internal rotor mounted within said external rotor on ashaft integral with said first mentioned shaft and non-concentric therewith, a plurality of slots in said internal rotor, varies in said slots and resting between said first and second mentioned plane surfaces, said vanes being adapted to divide the space between said rotors into a plurality of non-communicating chambers, a plurality of` recesses in said internal rotor, a plurality of pins fixed to said external rotor and engaging said recesses, said recessesl and pins being adapted to revolve said internal rotor synchronously with said external rotor, ports in said internalrotor communicating with each of said chambers, an intake passageway in the shaft of said internal rotor adapted to communicate with said ports and an exhaust passageway in the shaft of said internal rotor also adapted to communicate with said ports, a second intake passageway in the shaft of said internal rotor adapted to register with said ports and communicating with said first mentioned intake passageway to permit introduction of gaseous fluid into said chambers and adapted to start rotation of said rotors in a counterclockwise direction, a

register with said third mentioned intake passageway, another port in said slide valve adapted to register with said rst mentioned intake passageway and a plurality of exhaust ports in said slide valve adapted to register with the ports in said internal rotor.

2. An apparatus as in claim l wherein said exhaust ports in said slide valve are of sufficient size as to exhaust a plurality of chambers simultaneously.

3. In a gaseous uid engine, an external rotor provided with a plurality of plane surfaces and mounted on a shaft, projecting rings in said external roto-r provided with plane surfaces parallel to said .first mentioned plane surfaces, an internal rotor mounted within said external rotor on a shaft integral with said first mentioned shaft and non-concentric therewith, a plurality of slots in said internal rotor, vanes in. said slots and resting between said first and second mentioned plane surfaces, said vanes being adapted to divide the space between said rotors into a plurality of non-communicating chambers, a plurality of recesses in said internal rotor, a plurality of pins fixed vto said external rotor and engaging said recesses, said recesses and pins being adapted to revolve said internal rotor synchronously withy said external rotor, ports in said internal rotor communicating with each of said chambers, an intake passageway in the shaft of said internal rotor adapted to communicate with said ports and an exhaust passageway in the shaft of said internal rotor also adapted to communicate with said ports, a second intake passageway in the shaft of said internal rotor adapted to register with said ports and communicating with said first mentioned intake passageway to permit introduction of gaseous uid into said chambers and adapted to start rotation of said rotors in a counterclockwise direction, a third intake passageway adapted to register with said ports and communicating with said rst mentioned intake passageway to permit introduction of gaseous fluid into said chambers and adapted to start rotation of said rotors in a clockwise direction, a slide valve mounted on said shaft of said internal rotor and adapted to slide thereon, ports in said slide valve adapted to register with said second mentioned intake passageway, other ports in said slide valve adapted to register with said third mentioned intake passageway, another port in said slide valve adapted to register with said rst mentioned intake passageway, a plurality of exhaust ports in said slide valve adapted to register with the ports in said internal rotor, a rotary valve provided with a port and adapted to register with said first, second and third mentioned intake passageways.

4. In a gaseous fluid engine, an -external rotor comprising ran outside ring and a pair of cover plates mounted on each side of said ring, the inner circumference of said ring being provided with a plurality of equally spaced plane surfaces, and the central portions of. each cover plate being recessed, an eccentric shaft, the noneccentric portions of said shaft being Amounted within the recesses of said cover plates, projecting rings on the interior surfaces of said cover plates and concentric with said recesses of said cover plates, said projecting rings being provided with a plurality of plane surfaces parallel with the plane surfaces on said outside ring,y a plurality of equally spaced pins mounted between said cover plates and on a circle concentric with said projecting rings, an internal rotor provided with a centrally disposed recess and mounted on the eccentric portion of said eccentric shaft and provided with a plurality of equally spaced recesses, the circumferences thereof being adapted to engage the circumferences of said pins, whereby rotation of said external rotor will cause said internal rotor to revolve synchronously therewith, a plurality of equally spaced slots in said internal rotor, vanes in said slots the ends of which engage the plane surfaces of said projecting rings and the plane surfaces of said outside ring, said vanes being adapted to slide along said plane surfaces when said rotorsare rotated, said varies dividing the space between said rotors into as many non-communicating chambers as there are vanes, radially extending ports in said internal rotor terminating at one extremity into said chambers and at the other extremity in the centrally disposed recess of said internal rotor, a passageway in said eccentric communicating with steam for propelling said rotors, a second passageway in said eccentric adapted to carry spent gaseous fluid from said chambers, a slide valve unit provided with ports adapted to slide on the eccentric portion of said eccentric shaft, the ports of said slide valve unit being adapted to register with the ports in said internal rotor and with the passageways in said eccentric shaft.

5. In a gaseous iiuid engine, an external rotor, an internal rotor mounted within said external rotor on an axis non-concentric with that of said external rotor and operatively connected to said external rotor so as to revolve synchronously therewith and in the same direction, a plurality of vanes movably mounted in one of said rotors and movably engaged with the other so as to divide the space between said rotors into a plurality of non-communicating chambers, ports in said internal rotor communicating with each of said chambers, an intake passageway in the shaft of said internal rotor adapted to communicate with said ports and an exhaust passageway in the shaft of said internal rotor also adapted to communicate with said ports, a second intake passageway in the shaft of said internal rotor adapted to register with said ports and communicating with said rst mentioned intake passageway to permit introduction of gaseous fluid into said chambers and adapted to start rotation of said rotors in counterclockwise direction, a third intake passageway adapted to register with said ports and communicating with said rst mentioned intake passageway to permit introductionoi gaseous fluid into said chambers and adapted to start rotation of said rotors in a clockwise direction, a slide valve mounted on the shaft of said internal rotor and adapted to slide thereon, ports in said slide valve adapted to register with said second mentioned intake passageway, other ports in said slide Valve adapted to register' with said third mentioned intake passageway, another port in said slide valve adapted to register with said first mentioned intake passageway land a plurality of exhaust ports in said slide valve adapted to register with the ports in said internal rotor.

6. In a gaseous uid engine, an external rotor provided with a plurality of plane surfaces and mounted on a shaft, projecting rings in said external rotor provided with plane surfaces parallel to said first mentioned plane surfaces, an internal rotor mounted within said external rotor on a shaft integral with said first mentioned shaft and non-concentric therewith, a plurality of slots in said internal rotor, vanes in said slots and resting between said first and second mentioned plane surfaces, said vanes being adapted to divide the space between said rotor into a plurality of non-communicating chambers, a plurality of recesses in said internal rotor, a plurality of pins fixed to said external rotor and engaging said recesses, said recesses and pins being adapted to revolve said internal rotor synchronously with said external rotor, ports in said internal rotor communicating with each of said chambers, an intake passageway in the shaft of said internal rotor adapted to communicate with said ports and an exhaust passageway in the shaft of said internal rotor also adapted to communicate with said ports, a second intake passageway in the shaft of said internal rotor adapted to register with said ports and communicating with said first mentioned intake passageway to permit introduction of gaseous fluid into said chambers and adapted to start rotation of said rotors, a slide valve mounted on said shaft of said internal rotor and adapted to slide thereon, a port in said slide valve adapted to register with said second mentioned intake passageway, another port in said slide valve .adapted to register with said first mentioned intake passage- Way and an exhaust port in said slide Valve adapted to register with the ports in said internal rotor.

7. In a gaseous fluid engine, an external rotor mounted on a shaft, an internal rotor mounted within said external rotor and on a shaft eccentric with the shaft for said external rotor, a plurality of recesses in said internal rotor, pins in each of said recesses fixed to said external rotor, a plurality of radially disposed slots in said internal rotor, vanes in said slots movably engaged with said external rotor so as to divide the space between said rotors into a plurality of noncommunicating chambers, radial ports in said rotor adapted to communicate with said chambers, an intake and an exhaust passageway in the shaft of said internal rotor adapted to communicate with said ports, a second intake passageway in the shaft of said internal rotor communicating with said first mentioned passageway adapted to permit introduction of gaseous huid into said chambers to start rotation of said rotors, a slide valve mounted on said shaft of said internal rotor and adapted to slide thereon, a port in said slide valve adapted to register with said second mentioned intake passageway, another port in said slide valve adapted to register with said rst mentioned intake passageway and an exhaust port in said slide valve adapted to register with the ports in said internal rotor.

ROBERT L. BAILEY. 

